Difference between revisions of "Fibre - Nutrition"

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==What is Fibre?==
 
==What is Fibre?==
Fibres are '''polysaccharides''' that are resistant to hydrolysis by mammalian digestive enzymes. These include substances such as '''cellulose, hemi-cellulose, pectin''' and '''lignin''' which are '''key structural components of plant cell walls'''. Although fibre is most commonly associated with plant materials, fibre like substances such as chitin are present in fungi, crustaceans and insects. Over recent years the definition of dietary fibre has been expanded to include substances such as resistant starch, inulin and non-digestible oligosaccharides
+
Fibres are [[Nutrition Glossary#Polysaccharides|'''polysaccharides''']] that are resistant to hydrolysis by mammalian digestive enzymes. These include substances such as '''cellulose, hemi-cellulose, pectin''' and '''lignin''' which are '''key structural components of plant cell walls'''. Although fibre is most commonly associated with plant materials, fibre like substances such as chitin are present in fungi, crustaceans and insects. Over recent years the definition of dietary fibre has been expanded to include substances such as '''resistant starch, inulin''' and '''non-digestible oligosaccharides'''.
 
Fibre is resistant to degradation because mammalian digestive enzymes cannot break the glycoside linkages between sugar monomers.
 
Fibre is resistant to degradation because mammalian digestive enzymes cannot break the glycoside linkages between sugar monomers.
Fibres, can be classified by their capacity to dissolve in water (soluble or insoluble), form a gel-like consistency (viscous or non-viscous), and/or for fermentation by colonic bacteria (fermentable or non-fermentable)<ref>Luptin JR and Turner ND. Dietary Fiber. In Biochemical and Physiological Aspects of Human Nutrition. 2000 Philadelphia, PA: WB Saunders Company p.143-154.</ref>. Soluble, viscous, fermentable fibres are those that form gels within the gastrointestinal tracts, such as pectin, gums, mucilage, and some hemicelluloses. Insoluble, non-viscous, non-fermentable fibres remain relatively unchanged after consumption and include cellulose, lignin, and some hemicelluloses. Resistant starches are formed from absorbable starch during the cooking process and will act as fermentable fibre in the intestinal lumen.
+
'''Fibres can be classified by their capacity to dissolve in water (soluble or insoluble), form a gel-like consistency (viscous or non-viscous), and/or for fermentation by colonic bacteria (fermentable or non-fermentable)'''<ref>Luptin JR and Turner ND. Dietary Fiber. In Biochemical and Physiological Aspects of Human Nutrition. 2000 Philadelphia, PA: WB Saunders Company p.143-154.</ref>.  
 +
*Soluble, viscous, fermentable fibres are those that form gels within the [[Alimentary System Overview - Anatomy & Physiology|gastrointestinal tracts]], such as pectin, gums, mucilage, and some hemicelluloses.  
 +
*Insoluble, non-viscous, non-fermentable fibres remain relatively unchanged after consumption and include cellulose, lignin, and some hemicelluloses.  
 +
*Resistant starches are formed from absorbable starch during the cooking process and will act as fermentable fibre in the intestinal lumen.
  
 
==Why is it Important?==
 
==Why is it Important?==
'''Fibre is not considered an essential nutrient''', but both soluble, viscous, fermentable fibres and insoluble, non-viscous, non-fermentable fibres are '''important for normal physiologic function of the gastrointestinal tract'''. Depending on the type and amount of dietary fibre present, it can help regulate gastrointestinal motility and provide a source of nutrients for commensal colonic bacteria, which in turn can improve colonic function.
+
'''Fibre is not considered an [[Nutrition Glossary#Essential Nutrients|essential nutrient]]''', but both soluble, viscous, fermentable fibres and insoluble, non-viscous, non-fermentable fibres are '''important for normal physiologic function of the gastrointestinal tract'''. Depending on the type and amount of dietary fibre present, it can help regulate gastrointestinal motility and provide a source of nutrients for commensal colonic bacteria, which in turn can improve colonic function.
  
 
==Roles in the Body==
 
==Roles in the Body==
Increasing viscosity of ingesta will slow transit out of the [[Monogastric Stomach - Anatomy & Physiology|stomach]] and through the [[:Category:Small Intestine - Anatomy & Physiology|small intestine]]<ref>Bueno L, et al. Effect of dietary fiber on gastrointestinal motility and jejunal transit time in dogs. Gastroenter 1980;80:701-707.</ref><ref>Lewis LD, et al. Stool characteristics, transit time, and nutrient digestibility in dogs fed different fiber sources. J Nutr 1994;124:2716S-2718S.</ref>. This can promote a feeling of satiety, but can also delay or hinder nutrient absorption. The presence of viscous fibres can interfere with fat absorption<ref>Muir HE, et al. Nutrient digestion by ileal cannulated dogs as affected by dietary fibers with various fermentation characteristics. J Anim Sci 1996;74:1641-8.</ref><ref name="Mimura">Mimura K, et al. Impact of commercially available diabetic prescription diets on short term postprandial serum glucose, insulin, triglyceride and free fatty acid concentrations of obese cats. J Vet Med Sci 2013;75:929-937.</ref> and can slow starch digestion and glucose absorption, dampening post-prandial rises in blood sugar<ref name="Mimura"/><ref>Nguyen P, et al. Glycemic and insulinemic response after ingestion of commercial foods in healthy dogs: Influence of food composition. J Nutr 1998;128:2654S-2658S.</ref>.
+
Increasing viscosity of ingesta will slow transit out of the [[Monogastric Stomach - Anatomy & Physiology|stomach]] and through the [[:Category:Small Intestine - Anatomy & Physiology|small intestine]]<ref>Bueno L, et al. Effect of dietary fiber on gastrointestinal motility and jejunal transit time in dogs. Gastroenter 1980;80:701-707.</ref><ref>Lewis LD, et al. Stool characteristics, transit time, and nutrient digestibility in dogs fed different fiber sources. J Nutr 1994;124:2716S-2718S.</ref>. This can promote a feeling of satiety, but can also delay or hinder nutrient absorption. The presence of viscous fibres can interfere with [[Digestibility of Fat|fat absorption]]<ref>Muir HE, et al. Nutrient digestion by ileal cannulated dogs as affected by dietary fibers with various fermentation characteristics. J Anim Sci 1996;74:1641-8.</ref><ref name="Mimura">Mimura K, et al. Impact of commercially available [[DM|diabetic]] prescription diets on short term postprandial serum glucose, insulin, triglyceride and free fatty acid concentrations of obese cats. J Vet Med Sci 2013;75:929-937.</ref> and can slow [[Digestibility of Carbohydrates|starch digestion]] and glucose absorption, dampening post-prandial rises in blood sugar<ref name="Mimura"/><ref>Nguyen P, et al. Glycemic and insulinemic response after ingestion of commercial foods in healthy dogs: Influence of food composition. J Nutr 1998;128:2654S-2658S.</ref>.
  
Fermentable dietary fibres are utilized by bacteria within the large intestine to produce H<sub>2</sub> (hydrogen gas), CO<sub>2</sub> (carbon dioxide), CH<sub>4</sub> (methane), and the short-chain fatty acids, acetate, propionate, and butyrate. Acetate and propionate are rapidly absorbed across the large intestinal mucosa with [[Sodium - Nutrition|sodium]] (Na<sup>2+</sup>) and are responsible for water absorption in the [[:Category:Large Intestine - Anatomy & Physiology|large intestine]]<ref>Herschel DA, et al. Absorption of volatile fatty acids and H2O by the colon of the dog. AJVR 1981;42:1118-1124.</ref>. Acetate and propionate can then be further utilized by the host animal, and can contribute up to 10% of energy intake<ref>Rerat A. Digestion and absorption of carbohydrates and nitrogenous matters in the hindgut of the ombivorous nonruminant animal. J Anim Sci 1978;46:1808-1837.</ref>. Butyrate remains in the large intestine where it is used as the preferred energy substrate by colonocytes. Increased intake of fermentable fibre has been shown to increase colonic weight and villus height in dogs<ref>Reinhart GA, et al. Source of dietary fiber and its effects on colonic microstructure, function and histopathology of beagle dogs. J Nutr 1994;124:2701S-2703S.</ref>.
+
Fermentable dietary fibres are utilized by bacteria within the large intestine to produce H<sub>2</sub> (hydrogen gas), CO<sub>2</sub> (carbon dioxide), CH<sub>4</sub> (methane), and the short-chain fatty acids, acetate, propionate, and butyrate. Acetate and propionate are rapidly absorbed across the large intestinal mucosa with [[Sodium - Nutrition|sodium]] (Na<sup>2+</sup>) and are responsible for water absorption in the [[:Category:Large Intestine - Anatomy & Physiology|large intestine]]<ref>Herschel DA, et al. Absorption of volatile fatty acids and H2O by the colon of the dog. AJVR 1981;42:1118-1124.</ref>. Acetate and propionate can then be further utilized by the host animal, and can contribute up to 10% of energy intake<ref>Rerat A. Digestion and absorption of carbohydrates and nitrogenous matters in the hindgut of the ombivorous nonruminant animal. J Anim Sci 1978;46:1808-1837.</ref>. Butyrate remains in the large intestine where it is used as the preferred energy substrate by colonocytes. Increased intake of fermentable fibre has been shown to increase colonic weight and villus height in dogs<ref>Reinhart GA, et al. Source of dietary fiber and its effects on colonic microstructure, function and histopathology of beagle dogs. J Nutr 1994;124:2701S-2703S.</ref>.
Insoluble fibres will also increase faecal bulk and dry matter content<ref>Fahey GC Jr, et al. Dietary fiber for dogs. II. Isolated total dietary fiber (TDF_ additions of divergent fiber sources to dog diets and their effects on nutrient intake, digestibility, metabolic energy and digesta mean retention time. J Anim Sci 1990;68:4229-4235.</ref>, a feature that is used in some pet foods to dilute calorie density for weight management, though efficacy at decreasing energy intake is inconsistent<ref>German AJ, et al. A high protein high fibre diet improves weight loss in obese dogs. Vet J 2010;183:294-297. </ref><ref>Butterwick FR, et al. Effect of level and source of dietary fiber on food intake in the dog. J Nutr 1994;124:2695S-2700S.</ref>. Increased dietary fibre intake has also been used as an adjunct therapy to insulin administration to improve [[Nutrition Glosssary#Glycaemic Response|glycaemic response]] in diabetic cats and dogs<ref>Nelson RW. The role of fiber in managing diabetes mellitus. Vet Med 1989;84:1156-1160.</ref><ref>Nelson RW, et al. Effect of dietary insoluble fiber on control of glycemia in cats with naturally acquired diabetes mellitus. JAVMA 2000;216:1082-1088.</ref>. Decreased cholesterol and triglyceride absorption may also occur with increased intake of soluble, fermentable fibre<ref>Ikedo I, et al. Interrelated Effects of Dietary Fiber and Fat on Lymphatic Cholesterol and Triglyceride Absorption. J Nutr 1989;199:1383-1387.</ref>.
+
Insoluble fibres will also increase faecal bulk and dry matter content<ref>Fahey GC Jr, et al. Dietary fiber for dogs. II. Isolated total dietary fiber (TDF_ additions of divergent fiber sources to dog diets and their effects on nutrient intake, digestibility, metabolic energy and digesta mean retention time. J Anim Sci 1990;68:4229-4235.</ref>, a feature that is used in some pet foods to dilute calorie density for weight management, though efficacy at decreasing energy intake is inconsistent<ref>German AJ, et al. A high protein high fibre diet improves weight loss in obese dogs. Vet J 2010;183:294-297. </ref><ref>Butterwick FR, et al. Effect of level and source of dietary fiber on food intake in the dog. J Nutr 1994;124:2695S-2700S.</ref>. Increased dietary fibre intake has also been used as an adjunct therapy to [[insulin]] administration to improve [[Nutrition Glossary#Glycaemic Response|glycaemic response]] in diabetic cats and dogs<ref>Nelson RW. The role of fiber in managing diabetes mellitus. Vet Med 1989;84:1156-1160.</ref><ref>Nelson RW, et al. Effect of dietary insoluble fiber on control of glycemia in cats with naturally acquired diabetes mellitus. JAVMA 2000;216:1082-1088.</ref>. Decreased cholesterol and triglyceride absorption may also occur with increased intake of soluble, fermentable fibre<ref>Ikedo I, et al. Interrelated Effects of Dietary Fiber and Fat on Lymphatic Cholesterol and Triglyceride Absorption. J Nutr 1989;199:1383-1387.</ref>.
  
 
==Consequences of Fibre Deficiency==
 
==Consequences of Fibre Deficiency==
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==Toxicity==
 
==Toxicity==
Excessive intake of non-absorbable carbohydrates (both fermentable and non-fermentable dietary fibres) may potentially result in either diarrhoea or constipation in healthy dogs and cats depending on fibre type (viscous, fermentable vs. non-fermentable, respectively). Increased dietary fibre can also decrease protein digestibility<ref name="Kerr"/><ref>Silvio J, et al. Influences of fiber fermentation on nutrient digestion in the dog. Nutr 2000;16:289-295.</ref>, which may be contraindicated in animals with underlying intestinal disease, and high dietary fibre intake can interfere with mineral absorption<ref>Fernandez R and Phillips SF. Components of fiber impair iron absorption in the dog. Am J Clin Nutr 1982:35:107-112.</ref>. High intake of dietary fibre also results in energy dilution and animals may be unable to consume sufficient amounts of food to meet energy needs.
+
Excessive intake of non-absorbable carbohydrates (both fermentable and non-fermentable dietary fibres) may potentially result in either [[diarrhoea]] or [[Colonic Impaction - Dog and Cat|constipation]] in healthy dogs and cats depending on fibre type (viscous, fermentable vs. non-fermentable, respectively). Increased dietary fibre can also decrease [[Digestibility of Protein|protein digestibility]]<ref name="Kerr"/><ref>Silvio J, et al. Influences of fiber fermentation on nutrient digestion in the dog. Nutr 2000;16:289-295.</ref>, which may be contraindicated in animals with underlying intestinal disease, and high dietary fibre intake can interfere with mineral absorption<ref>Fernandez R and Phillips SF. Components of fiber impair iron absorption in the dog. Am J Clin Nutr 1982:35:107-112.</ref>. High intake of dietary fibre also results in energy dilution and animals may be unable to consume sufficient amounts of food to meet [[Energy - Nutrition|energy needs]].
  
 
==Dietary Sources==
 
==Dietary Sources==
Dietary fibre is found in fruits, vegetables, cereal grains, and pulses (i.e., legumes). Chitin is present in fungi and the exoskeleton of crustaceans and insects. Common pet food fibre sources, such as beet pulp and fruit (e.g., citrus, tomato, apple) pomaces are derived from the human food industry.  
+
Dietary fibre is found in fruits, vegetables, cereal grains, and pulses (i.e. legumes). Chitin is present in fungi and the exoskeleton of crustaceans and insects. Common pet food fibre sources, such as beet pulp and fruit (e.g. citrus, tomato, apple) pomaces are derived from the human food industry.  
Crude fibre as listed on a pet food label is a measure of insoluble, non-fermentable fraction of total dietary fibre and does not reflect the actual amount or distribution of fibre within a commercial diet<ref>Farcas AK, et al. Evaluation of fiber concentration in dry and canned commercial diets formulated for adult maintenance or all life stages of dogs by use of crude fiber and total dietary fiber methods. JAVMA 2013;242:936–940.</ref>.
+
'''Crude fibre as listed on a pet food label is a measure of insoluble, non-fermentable fraction of total dietary fibre and does not reflect the actual amount or distribution of fibre within a commercial diet'''<ref>Farcas AK, et al. Evaluation of fiber concentration in dry and canned commercial diets formulated for adult maintenance or all life stages of dogs by use of crude fiber and total dietary fiber methods. JAVMA 2013;242:936–940.</ref>.
  
 
==Diagnosing Fibre Deficiency==
 
==Diagnosing Fibre Deficiency==
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==References==
 
==References==
 
<references/>
 
<references/>
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{{Reviewed Nutrition 1
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|date = 18 May 2015}}
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{{Waltham}}
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{{OpenPages}}
  
 
[[Category:Carbohydrates]]
 
[[Category:Carbohydrates]]
[[Category:To Do - Nutrition]]
 
[[Category:To Do - Nutrition GGP]]
 

Latest revision as of 08:35, 11 May 2016

What is Fibre?

Fibres are polysaccharides that are resistant to hydrolysis by mammalian digestive enzymes. These include substances such as cellulose, hemi-cellulose, pectin and lignin which are key structural components of plant cell walls. Although fibre is most commonly associated with plant materials, fibre like substances such as chitin are present in fungi, crustaceans and insects. Over recent years the definition of dietary fibre has been expanded to include substances such as resistant starch, inulin and non-digestible oligosaccharides. Fibre is resistant to degradation because mammalian digestive enzymes cannot break the glycoside linkages between sugar monomers. Fibres can be classified by their capacity to dissolve in water (soluble or insoluble), form a gel-like consistency (viscous or non-viscous), and/or for fermentation by colonic bacteria (fermentable or non-fermentable)[1].

  • Soluble, viscous, fermentable fibres are those that form gels within the gastrointestinal tracts, such as pectin, gums, mucilage, and some hemicelluloses.
  • Insoluble, non-viscous, non-fermentable fibres remain relatively unchanged after consumption and include cellulose, lignin, and some hemicelluloses.
  • Resistant starches are formed from absorbable starch during the cooking process and will act as fermentable fibre in the intestinal lumen.

Why is it Important?

Fibre is not considered an essential nutrient, but both soluble, viscous, fermentable fibres and insoluble, non-viscous, non-fermentable fibres are important for normal physiologic function of the gastrointestinal tract. Depending on the type and amount of dietary fibre present, it can help regulate gastrointestinal motility and provide a source of nutrients for commensal colonic bacteria, which in turn can improve colonic function.

Roles in the Body

Increasing viscosity of ingesta will slow transit out of the stomach and through the small intestine[2][3]. This can promote a feeling of satiety, but can also delay or hinder nutrient absorption. The presence of viscous fibres can interfere with fat absorption[4][5] and can slow starch digestion and glucose absorption, dampening post-prandial rises in blood sugar[5][6].

Fermentable dietary fibres are utilized by bacteria within the large intestine to produce H2 (hydrogen gas), CO2 (carbon dioxide), CH4 (methane), and the short-chain fatty acids, acetate, propionate, and butyrate. Acetate and propionate are rapidly absorbed across the large intestinal mucosa with sodium (Na2+) and are responsible for water absorption in the large intestine[7]. Acetate and propionate can then be further utilized by the host animal, and can contribute up to 10% of energy intake[8]. Butyrate remains in the large intestine where it is used as the preferred energy substrate by colonocytes. Increased intake of fermentable fibre has been shown to increase colonic weight and villus height in dogs[9]. Insoluble fibres will also increase faecal bulk and dry matter content[10], a feature that is used in some pet foods to dilute calorie density for weight management, though efficacy at decreasing energy intake is inconsistent[11][12]. Increased dietary fibre intake has also been used as an adjunct therapy to insulin administration to improve glycaemic response in diabetic cats and dogs[13][14]. Decreased cholesterol and triglyceride absorption may also occur with increased intake of soluble, fermentable fibre[15].

Consequences of Fibre Deficiency

Dogs:

There are not consistent clinical signs of feeding a fibre-free diet to dogs. In otherwise healthy adult dogs, decreasing dietary fibre intake will decrease frequency of defecation and decrease faecal water content[16]. Some dogs with recurrent idiopathic colitis may benefit from feeding higher fibre diets[17].

Cats:

Healthy cats can be fed a fibre-free diet without apparent clinical signs or changes in stool quality[18], but inclusion of fermentable fibres may improve indices of colonic health in cats[19].

Toxicity

Excessive intake of non-absorbable carbohydrates (both fermentable and non-fermentable dietary fibres) may potentially result in either diarrhoea or constipation in healthy dogs and cats depending on fibre type (viscous, fermentable vs. non-fermentable, respectively). Increased dietary fibre can also decrease protein digestibility[18][20], which may be contraindicated in animals with underlying intestinal disease, and high dietary fibre intake can interfere with mineral absorption[21]. High intake of dietary fibre also results in energy dilution and animals may be unable to consume sufficient amounts of food to meet energy needs.

Dietary Sources

Dietary fibre is found in fruits, vegetables, cereal grains, and pulses (i.e. legumes). Chitin is present in fungi and the exoskeleton of crustaceans and insects. Common pet food fibre sources, such as beet pulp and fruit (e.g. citrus, tomato, apple) pomaces are derived from the human food industry. Crude fibre as listed on a pet food label is a measure of insoluble, non-fermentable fraction of total dietary fibre and does not reflect the actual amount or distribution of fibre within a commercial diet[22].

Diagnosing Fibre Deficiency

Diagnosis is based on response to feeding of a higher fibre diet. For diabetic dogs and cats, improvement in glycaemic control may be seen with addition of dietary fibre. In animals experiencing colitis-like signs, the inclusion of both soluble, fermentable, and insoluble, non-fermentable fibre types may resolve clinical signs.

References

  1. Luptin JR and Turner ND. Dietary Fiber. In Biochemical and Physiological Aspects of Human Nutrition. 2000 Philadelphia, PA: WB Saunders Company p.143-154.
  2. Bueno L, et al. Effect of dietary fiber on gastrointestinal motility and jejunal transit time in dogs. Gastroenter 1980;80:701-707.
  3. Lewis LD, et al. Stool characteristics, transit time, and nutrient digestibility in dogs fed different fiber sources. J Nutr 1994;124:2716S-2718S.
  4. Muir HE, et al. Nutrient digestion by ileal cannulated dogs as affected by dietary fibers with various fermentation characteristics. J Anim Sci 1996;74:1641-8.
  5. 5.0 5.1 Mimura K, et al. Impact of commercially available diabetic prescription diets on short term postprandial serum glucose, insulin, triglyceride and free fatty acid concentrations of obese cats. J Vet Med Sci 2013;75:929-937.
  6. Nguyen P, et al. Glycemic and insulinemic response after ingestion of commercial foods in healthy dogs: Influence of food composition. J Nutr 1998;128:2654S-2658S.
  7. Herschel DA, et al. Absorption of volatile fatty acids and H2O by the colon of the dog. AJVR 1981;42:1118-1124.
  8. Rerat A. Digestion and absorption of carbohydrates and nitrogenous matters in the hindgut of the ombivorous nonruminant animal. J Anim Sci 1978;46:1808-1837.
  9. Reinhart GA, et al. Source of dietary fiber and its effects on colonic microstructure, function and histopathology of beagle dogs. J Nutr 1994;124:2701S-2703S.
  10. Fahey GC Jr, et al. Dietary fiber for dogs. II. Isolated total dietary fiber (TDF_ additions of divergent fiber sources to dog diets and their effects on nutrient intake, digestibility, metabolic energy and digesta mean retention time. J Anim Sci 1990;68:4229-4235.
  11. German AJ, et al. A high protein high fibre diet improves weight loss in obese dogs. Vet J 2010;183:294-297.
  12. Butterwick FR, et al. Effect of level and source of dietary fiber on food intake in the dog. J Nutr 1994;124:2695S-2700S.
  13. Nelson RW. The role of fiber in managing diabetes mellitus. Vet Med 1989;84:1156-1160.
  14. Nelson RW, et al. Effect of dietary insoluble fiber on control of glycemia in cats with naturally acquired diabetes mellitus. JAVMA 2000;216:1082-1088.
  15. Ikedo I, et al. Interrelated Effects of Dietary Fiber and Fat on Lymphatic Cholesterol and Triglyceride Absorption. J Nutr 1989;199:1383-1387.
  16. Fahey GC, et al. Dietary fiber for dogs: 1. Effects of graded levels of dietary beet pulp on nutrient intake, digestibility, metabolizable energy and digesta mean retention time. J Anim Sci 1990;68:4221-4228.
  17. Leib MS. Treatment of chronic idiopathic large-bowel diarrhea in dogs with a highly digestible diet and soluble fiber: a retrospective review of 37 cases. JVIM 2000;14:27-32.
  18. 18.0 18.1 Kerr KR, et al. Apparent total tract energy and macronutrient digestibility and fecal fermentative end-product concentrations of domestic cats fed extruded, raw beef-based, and cooked beef-based diets. J Anim Sci 2012;90:515-522.
  19. Kanakupt K, et al. Effects of short-chain fructooligosaccharides and galactooligosaccharides, individually and in combination, on nutrient digestibility, fecal fermentative metabolite concentrations, and large bowel microbial ecology of healthy adults cats. J Anim Sci 2011;89:1376-1384.
  20. Silvio J, et al. Influences of fiber fermentation on nutrient digestion in the dog. Nutr 2000;16:289-295.
  21. Fernandez R and Phillips SF. Components of fiber impair iron absorption in the dog. Am J Clin Nutr 1982:35:107-112.
  22. Farcas AK, et al. Evaluation of fiber concentration in dry and canned commercial diets formulated for adult maintenance or all life stages of dogs by use of crude fiber and total dietary fiber methods. JAVMA 2013;242:936–940.



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